How to maintain NiMH Battery

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How to maintain NiMH Battery?
NiMH battery outperforms other rechargeable batteries and has higher capacity and less voltage
depression. These properties make them ideal for use in high drain devices like digital camera.
The toxic Cadmium is absent in NiMH battery so it is the most Eco friendly one.
The NiMH battery is similar to NiCd cells in structure but it uses a hydrogen absorbing alloy as
negative electrode instead of cadmium. The positive electrode is a nickel oxy hydroxide
(NiOOH).Alkaline batteries have approximately 3000 mAh capacity with a 1000 mA load. Digital
camera with LCD and flash light can draw over 1000 mA quickly and depleting the alkaline batteries
after a few shots. NiMH batteries on the other hand can easily handle the high current levels and
maintain their full capacity. AA type NiMH cells have a nominal capacity (C) ranging from 1000 mAh
to 2700 mAh at 1.2 volts with a discharge rate of 0.2C / hour.
What is inside?
The NiMH battery has a special chemistry.There is an ‘Inter metallic compound in the NiMH
battery’. Most NiMH cells use AB5 or AB2 type metallic compounds. The common one is AB5
where ‘A’ represents a rare earth mixture of lanthanum, cerium, neodymium, praseodymium or
titanium. The ‘B’ represents nickel, cobalt, manganese etc. But some NiMH cells use higher
capacity negative materials based on AB2 compounds. Here ‘A’ represents titanium or vanadium and
‘B’ is nickel modified with chromium, cobalt iron etc. The metallic compound reversibly forms a
mixture of ‘metal hydride compound’. When the battery is undergoing charging process, hydrogen
ions are forced out of potassium hydroxide electrolyte solution by the charging voltage. This avoids the
formation of gas inside. During the discharge process, the same ions are released to participate in the
reverse reaction. When over charged at low current, oxygen produced at the positive electrode passes
through the separator and recombines at the surface of the negative electrode. Hydrogen production is
suppressed and the charging energy converts to heat. This makes the NiMH battery maintenance free.
Features of NiMH Battery
Voltage
Typical NiMH battery is rated 1.2 volts/cell. This is the nominal voltage of the cell that is discharging
at the rate of C/10 at 25 degree centigrade to an end voltage of 1 volt. The battery pack has three 1.2
volt cells making a total 3.6 volts. When a fully charged battery is used, the discharge voltage starts
from 1.5 volts followed by a sharp drop to 1.3 volts. The voltage in the cell remains 1.3 volts to 1.2
volts until another voltage drop occurs during a deep discharge. The nominal voltage of the battery can
be calculated by dividing the battery power by its capacity
Nominal voltage = Wh / Ah. That is Watt hour / Ampere hour
Charge Efficiency
It is the ratio (in percentage) of the charge removed from the battery during discharge compared to the
energy used during charging to restore the original capacity. It is also called’ Charge
Acceptance’or‘Coulombic Charge’. Charge efficiency is adversely affected by temperature. Low
temperature reduce charge acceptance and increase charge time.
Rate capacity
It is the maximum rate a battery cell can charge or discharge. ’Capacity’ refers to the electric current
in
the
battery
which
is
expressed
in Ampere-Hour(Ah)
or
MilliAmpereHour(mAh).Abbreviation ‘C’ represents the rated capacity of the battery. That is the battery charge or
discharge CmA for one hour or 2C for 30 minutes. In NiMH cells, the capacity is usually
represented in mAh. The ‘rated capacity’ of the battery can be calculated by multiplying the time taken
to discharge the battery to the end voltage by the rate of discharge current.
For example, a 1500 mAh battery takes 1 hour to attain 1 volt per cell if it is discharged at the rate of
150 mA. The rate current denoted as ‘C’ is either charge or discharge current in the battery. If 1500
mAh is discharging at the rate of C/2 will have a discharge current of 750 mA per hour. The rated
capacity of the battery is not the capacity obtained for use but its charging/discharging rate.
Internal impedance
When battery provides current, a resistance develops inside the battery. This is called internal
impedance. It includes both dc and ac resistance. The internal impedance of NiMH battery is too small
and the electrode easily becomes polarized and a polarization resistance will be produced while
measuring the dc resistance. So that it is difficult to measure the accurate value
.
Self discharge
A fully charged battery loss it capacity when not in use for long time. The self discharge rate of NiMH
battery is 5-10% on the first day. Self discharging property makes NiMH battery unsuitable for many
light duty uses such as digital clocks, remote control devices etc where battery would normally be
expected to last many months. Temperature at which the battery is stored is very important. Higher
temperature above 55 degree increases self discharge rate.
Memory effect
‘Memory effect’ which causes the battery to ‘remember’ how much charge was released on previous
discharge. So that the same amount of energy is released with every charge/discharge cycle. The
battery then keeps the ‘memory’ of the primary platform and considers it as the end of discharge for
the next cycle even though the battery can be discharged further. If a ‘memory effect’ develops, during
the next discharge cycle, battery only remembers this. Memory effect is less in NiMH battery
Voltage depression
When the battery is discharged below 0.8 volt per cell, one weaker cell may goes to zero volt first. If
the battery is deeply discharged, it charges in the ‘reverse’ direction. This creates “Voltage depression”
and the battery performance suddenly drops. So in order to avoid this problem, it is necessary to charge
the battery when it holds less than 5% of C.
Over charge
When the battery is charging continuously after it gets fully charged, the positive capacity becomes
higher than the negative, resulting in oxygen generation from the positive which passes to the negative
side. If the charge current is too high or charging time is prolonged, the generated oxygen cannot be
used up in time. This creates high internal pressure leading to battery distortion and damage.
Over discharge
When the battery attains the specified voltage, it still posses the ability to discharge the stored current.
In NiMH cells, the safe ‘end voltage’ limit of individual cell in the pack is 1 volt at 0.2C to 2C. If the
cell is discharging below this end voltage, say for example 0.8 volt per cell at 3C or more, over
discharge takes place.
Short circuit
If the NiMH battery terminals are shorted with a conductive material (even moisture), the electrolyte
pressure and internal gas pressure increases suddenly, and the electrolyte leak out from the battery and
in extreme cases battery will explode.
Charging Method
If it is properly maintained, the life of the battery NiMH battery can be extended up to 2 years
depending on the use. The basic parameters involved in NiMH battery charging are
Charge current
NiMH battery is a high current device holding more than 3000 mAh current. So charging current and
voltage are very important aspects. Current required for the battery depends on its capacity’C’ which is
expressed in Ah or mAh in the battery specification. For example, if the ‘C’ value of the battery pack
is 1300 mAh, it requires 1.3Ah (1300 mAh)current to get fully charged. The charging current can be
calculated using the formula
0.1C / mAh
If the capacity C is 1300 mAh, then the required current for normal charging is
0.1C / 1300. That is 130 mA.
1C of 1300 mAh battery equals 1300 mAh current
Charge voltage
About 1.4 to 1.6 volt per cell is needed for NiMH battery pack for charging. A fully charged cell
measures 1.35 to 1.4 volts in the unloaded condition. During discharge the cell can provide 1.2 volts
down to 1 volt. If the voltage level decreases below 0.8 volts, the cell may be permanently damaged.
What happens during charging?
Charging is the’ pumping’ of electrical energy in the chemical content of the cell. Continuous pumping
of current faster than the chemical reaction to accept the charge can reduce the ‘charge accepting
property’ of the chemicals inside the battery cell. This leads to polarization, overheating and corrosion
of electrodes etc. The reason for this is that here is a ‘reaction gradient’ exists between the electrodes in
the electrolyte. The electrolyte close to the electrode ‘charge’ first and then the electrolyte far away
from the electrode.
Two important chemical changes take place during charging. These are ‘Charge transfer’ and ‘Mass
transport’. In charge transfer, actual chemical reaction takes place in the electrolyte close to the
electrodes. Mass transport is the movement or diffusion of materials formed during charge transfer
from the surface of electrodes. So that further molecules can take part in the chemical reaction. Charge
transfer is a fast process while mass transport is a relatively slow process continuing till all the
materials in the electrolyte are transformed.
The time required for charge transfer is very low. That is 1 minute or less. But mass transport requires
several hours to complete. These two phenomena are applicable in charging and discharging.
Continuous pumping of current in fast or quick charge, causes ‘quick charge transfer’ so that there will
not be sufficient time for mass transport. This will adversely affect the battery chemistry leading to
passivation of electrolyte, crystal formation, gas accumulation, polarization etc. These “Parasitic
effects” reduce the charge acceptance of the cell leading to poor performance. The best method to
balance the charge transfer and mass transport is to provide ‘rest periods’ during the charging process.
This can be done by interrupting the charging current for one or more times for a short period to
stabilize the chemical reaction.
Better care – better performance
It is important to consider the following to keep the NiMH battery in top condition.
NiMH cells are good for 500 to 1000 cycles if properly charged. A new battery needs full charging
(Reforming) before use. It should be `charged and discharged minimum 5 times to attain full charge
capacity. When a new NiMH battery is charged and connected to equipment, it will show full charge
only for 10-15 minutes. If this occurs, remove the battery and allow it to cool for 15 minutes and then
charge. Fast charging with 100%C should be terminated after 1.5 hours. Charger should be switched
off if the battery temperature rises above 55 degree centigrade. Do not discharge the entire cells in the
battery pack below 0.8 volt per cell to avoid voltage depression. NiMH cells do not accept full charge
and discharge if the temperature is above 50 degree and below 0 degree. NiMH cells like 0-40 degree
temperature. NiMH cells can hold full charge for a month if stored in normal temperature. If it is kept
near hot objects or exposed in sunlight for hours, the charge will drop in one day. ‘Condition’ the
battery once in a month. This is done by completely discharging the battery by running the equipment
in battery power and then allows to charge completely.
If the battery is not used for long periods, first charge the battery fully and then remove it from the
equipment and store in a cool dry place. Recharge again once in a month. Do not charge NiMH battery
using raw DC (12or 24 V) available from the outlets of car or aircrafts since the voltage and current are
not regulated. If emergency charging is required from such power sources, use a voltage and current
regulator circuit in the charger. Do not ‘flatten’ the battery below 0.8V/cell and do not over charge
beyond 100%C
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